/*
 * This software is part of the SBCL system. See the README file for
 * more information.
 *
 * This software is derived from the CMU CL system, which was
 * written at Carnegie Mellon University and released into the
 * public domain. The software is in the public domain and is
 * provided with absolutely no warranty. See the COPYING and CREDITS
 * files for more information.
 */

#include <stdio.h>

#include "genesis/sbcl.h"
#include "runtime.h"
#include "globals.h"
#include "validate.h"
#include "os.h"
#include "arch.h"
#include "lispregs.h"
#include "interrupt.h"
#include "interr.h"
#include "breakpoint.h"
#include "thread.h"
#include "pseudo-atomic.h"
#include "gc.h"
#include "var-io.h"
#include "code.h"
#include "align.h"

#include "genesis/static-symbols.h"
#include "genesis/symbol.h"
#include "genesis/vector.h"

#define INT3_INST 0xcc
#define UD2_INST 0x0b0f
#define BREAKPOINT_WIDTH 1

#ifndef LISP_FEATURE_WIN32
os_vm_address_t
arch_get_bad_addr(int sig, siginfo_t *code, os_context_t *context)
{
    return (os_vm_address_t)code->si_addr;
}
#endif


/*
 * hacking signal contexts
 *
 * (This depends both on architecture, which determines what we might
 * want to get to, and on OS, which determines how we get to it.)
 */

void visit_context_registers(void (*proc)(os_context_register_t,void*),
                             os_context_t *context, void* arg)
{
    proc(os_context_pc(context), arg);
    proc(*os_context_register_addr(context,reg_EAX), arg);
    proc(*os_context_register_addr(context,reg_ECX), arg);
    proc(*os_context_register_addr(context,reg_EDX), arg);
    proc(*os_context_register_addr(context,reg_EBX), arg);
    proc(*os_context_register_addr(context,reg_ESI), arg);
    proc(*os_context_register_addr(context,reg_EDI), arg);
}

int *
os_context_flags_addr(os_context_t *context)
{
#if defined __linux__
    /* KLUDGE: As of kernel 2.2.14 on Red Hat 6.2, there's code in the
     * <sys/ucontext.h> file to define symbolic names for offsets into
     * gregs[], but it's conditional on __USE_GNU and not defined, so
     * we need to do this nasty absolute index magic number thing
     * instead. */
    return &context->uc_mcontext.gregs[16];
#elif defined(LISP_FEATURE_SUNOS)
    return &context->uc_mcontext.gregs[EFL];
#elif defined(LISP_FEATURE_FREEBSD) || defined(__DragonFly__)
    return &context->uc_mcontext.mc_eflags;
#elif defined __OpenBSD__
    return &context->sc_eflags;
#elif defined LISP_FEATURE_DARWIN
    return (int *)(&context->uc_mcontext->SS.EFLAGS);
#elif defined __NetBSD__
    return &(context->uc_mcontext.__gregs[_REG_EFL]);
#elif defined LISP_FEATURE_WIN32
    return (int *)&context->win32_context->EFlags;
#else
#error unsupported OS
#endif
}

void arch_skip_instruction(os_context_t *context)
{
    /* Assuming we get here via an INT3 xxx instruction, the PC now
     * points to the interrupt code (a Lisp value) so we just move
     * past it. Skip the code; after that, if the code is an
     * error-trap or cerror-trap then skip the data bytes that follow. */

    int code;

    /* Get and skip the Lisp interrupt code. */
    code = *(char*)(OS_CONTEXT_PC(context)++);
    switch (code)
        {
        case trap_Error:
        case trap_Cerror:
            skip_internal_error(context);
            break;

        case trap_Breakpoint:           /* not tested */
        case trap_FunEndBreakpoint: /* not tested */
            break;

#ifdef LISP_FEATURE_SB_SAFEPOINT
        case trap_GlobalSafepoint:
        case trap_CspSafepoint:
#endif
        case trap_PendingInterrupt:
        case trap_Halt:
        case trap_SingleStepAround:
        case trap_SingleStepBefore:
            /* only needed to skip the Code */
            break;

        default:
            fprintf(stderr,"[arch_skip_inst invalid code %d\n]\n",code);
            break;
        }

}

unsigned char *
arch_internal_error_arguments(os_context_t *context)
{
    return 1 + (unsigned char *)(OS_CONTEXT_PC(context));
}

bool arch_pseudo_atomic_atomic(struct thread *thread) {
    return get_pseudo_atomic_atomic(thread);
}

void arch_set_pseudo_atomic_interrupted(struct thread *thread) {
    set_pseudo_atomic_interrupted(thread);
}

void arch_clear_pseudo_atomic_interrupted(struct thread *thread) {
    clear_pseudo_atomic_interrupted(thread);
}

/*
 * This stuff seems to get called for TRACE and debug activity.
 */

unsigned int
arch_install_breakpoint(void *pc)
{
    unsigned int result = *(unsigned int*)pc;
    *(char*)pc = INT3_INST;
    *((char*)pc+1) = trap_Breakpoint;           /* Lisp trap code */
    return result;
}

void
arch_remove_breakpoint(void *pc, unsigned int orig_inst)
{
    *((char *)pc) = orig_inst & 0xff;
    *((char *)pc + 1) = (orig_inst & 0xff00) >> 8;
}

/* When single stepping, single_stepping holds the original instruction
 * PC location. */
unsigned int *single_stepping = NULL;
#ifdef CANNOT_GET_TO_SINGLE_STEP_FLAG
unsigned int  single_step_save1;
unsigned int  single_step_save2;
unsigned int  single_step_save3;
#endif

void
arch_do_displaced_inst(os_context_t *context, unsigned int orig_inst)
{
    unsigned int *pc = (unsigned int*)OS_CONTEXT_PC(context);

    /* Put the original instruction back. */
    arch_remove_breakpoint(pc, orig_inst);

#ifdef CANNOT_GET_TO_SINGLE_STEP_FLAG
    /* Install helper instructions for the single step:
     * pushf; or [esp],0x100; popf. */
    single_step_save1 = *(pc-3);
    single_step_save2 = *(pc-2);
    single_step_save3 = *(pc-1);
    *(pc-3) = 0x9c909090;
    *(pc-2) = 0x00240c81;
    *(pc-1) = 0x9d000001;
#else
    *os_context_flags_addr(context) |= 0x100;
#endif

    single_stepping = pc;

#ifdef CANNOT_GET_TO_SINGLE_STEP_FLAG
    OS_CONTEXT_PC(context) = (os_context_register_t)((char *)pc - 9);
#endif
}

void
restore_breakpoint_from_single_step(os_context_t * context)
{
    /* fprintf(stderr,"* single step trap %x\n", single_stepping); */
#ifdef CANNOT_GET_TO_SINGLE_STEP_FLAG
    /* Un-install single step helper instructions. */
    *(single_stepping-3) = single_step_save1;
    *(single_stepping-2) = single_step_save2;
    *(single_stepping-1) = single_step_save3;
#else
    *os_context_flags_addr(context) &= ~0x100;
#endif
    /* Re-install the breakpoint if possible. */
    if (((char *)OS_CONTEXT_PC(context) > (char *)single_stepping) &&
        ((char *)OS_CONTEXT_PC(context) <= (char *)single_stepping + BREAKPOINT_WIDTH)) {
        fprintf(stderr, "warning: couldn't reinstall breakpoint\n");
    } else {
        arch_install_breakpoint(single_stepping);
    }

    single_stepping = NULL;
    return;
}

void
arch_handle_breakpoint(os_context_t *context)
{
    OS_CONTEXT_PC(context) -= BREAKPOINT_WIDTH;
    handle_breakpoint(context);
}

void
arch_handle_fun_end_breakpoint(os_context_t *context)
{
    OS_CONTEXT_PC(context) -= BREAKPOINT_WIDTH;
    OS_CONTEXT_PC(context) = (int)handle_fun_end_breakpoint(context);
}

void
arch_handle_single_step_trap(os_context_t *context, int trap)
{
    arch_skip_instruction(context);
    /* On x86 the fdefn / function is always in EAX, so we pass 0
     * as the register_offset. */
    handle_single_step_trap(context, trap, 0);
}

#ifndef LISP_FEATURE_WIN32
void
sigtrap_handler(int signal, siginfo_t *info, os_context_t *context)
{
    unsigned int trap;

    if (single_stepping) {
        restore_breakpoint_from_single_step(context);
        return;
    }

    /* This is just for info in case the monitor wants to print an
     * approximation. */
    access_control_stack_pointer(get_sb_vm_thread()) =
        (lispobj *)*os_context_sp_addr(context);

#ifdef LISP_FEATURE_SUNOS
    /* For some reason the breakpoints that :ENCAPSULATE NIL tracing sets up
     * cause a trace trap (i.e. processor single-stepping trap) on the following
     * instruction on Solaris 10/x86. -- JES, 2006-04-07
     */
    if (info->si_code == TRAP_TRACE) {
        lose("foo");
        return;
    }
#endif

    /* On entry %eip points just after the INT3 byte and aims at the
     * 'kind' value (eg trap_Cerror). For error-trap and Cerror-trap a
     * number of bytes will follow, the first is the length of the byte
     * arguments to follow. */
    trap = *(unsigned char *)OS_CONTEXT_PC(context);
    handle_trap(context, trap);
}

void
sigill_handler(int signal, siginfo_t *siginfo, os_context_t *context) {
    if (*(unsigned short *)OS_CONTEXT_PC(context) == UD2_INST) {
        OS_CONTEXT_PC(context) += 2;
        return sigtrap_handler(signal, siginfo, context);
    }
    fake_foreign_function_call(context);
    lose("Unhandled SIGILL at %p.", (void*)OS_CONTEXT_PC(context));
}
#endif /* not LISP_FEATURE_WIN32 */

void
arch_install_interrupt_handlers()
{
    /* Note: The old CMU CL code here used sigtrap_handler() to handle
     * SIGILL as well as SIGTRAP. I couldn't see any reason to do
     * things that way. So, I changed to separate handlers when
     * debugging a problem on OpenBSD, where SBCL wasn't catching
     * SIGILL properly, but was instead letting the process be
     * terminated with an "Illegal instruction" output. If this change
     * turns out to break something (maybe breakpoint handling on some
     * OS I haven't tested on?) and we have to go back to the old CMU
     * CL way, I hope there will at least be a comment to explain
     * why.. -- WHN 2001-06-07 */
#ifndef LISP_FEATURE_WIN32
    ll_install_handler(SIGILL , sigill_handler);
    ll_install_handler(SIGTRAP, sigtrap_handler);
#endif
}


void
gencgc_apply_code_fixups(struct code *old_code, struct code *new_code)
{
    lispobj fixups = barrier_load(&new_code->fixups);
    /* It will be a nonzero integer if valid, or 0 if there are no fixups */
    if (!fixups) return;

    char* code_start_addr = code_text_start(new_code);
    os_vm_size_t displacement = (char*)new_code - (char*)old_code;
    /* Got the fixups for the code block. Now work through them
       in order, first the absolute ones, then the relative.
       Locations are sorted and delta-encoded for compactness. */
    struct varint_unpacker unpacker;
    varint_unpacker_init(&unpacker, fixups);
    int prev_offset = 0, offset;
    // Absolute fixups all refer to this object itself (the code
    // boxed constants). Add this object's displacement to the
    // value that currently exists at the fixup location.
    while (varint_unpack(&unpacker, &offset) && offset != 0) {
        offset += prev_offset;
        prev_offset = offset;
        *(char**)(code_start_addr + offset) += displacement;
    }
    prev_offset = 0;
    // Relative fixups: assembly and foreign routines. Subtract this
    // object's displacement from the value that currently exists.
    while (varint_unpack(&unpacker, &offset) && offset != 0) {
        offset += prev_offset;
        prev_offset = offset;
        *(char**)(code_start_addr + offset) -= displacement;
    }
}

void
arch_write_linkage_table_entry(int index, void *target_addr, int datap)
{
    // 'volatile' works around a spurious GCC warning
    volatile char *reloc_addr = (char*)ALIEN_LINKAGE_SPACE_START + index * ALIEN_LINKAGE_TABLE_ENTRY_SIZE;
    if (datap) {
        *(unsigned long *)reloc_addr = (unsigned long)target_addr;
        return;
    }
    /* Make JMP to function entry. JMP offset is calculated from next
     * instruction.
     */
    long offset = (char *)target_addr - (reloc_addr + 5);
    int i;

    *reloc_addr++ = 0xe9;       /* opcode for JMP rel32 */
    for (i = 0; i < 4; i++) {
        *reloc_addr++ = offset & 0xff;
        offset >>= 8;
    }

    /* write a nop for good measure. */
    *reloc_addr = 0x90;
}

#include "x86-arch-shared.inc"
